• 教师名录

基本信息
姓名:徐洪涛
通讯地址:第二办公楼308
电话:021-55272015
邮箱:htxu@usst.edu.cn;bsenergy@foxmail.com
主要研究领域:多相多组分传热与传质机理;工业燃烧及污染物生成与防治;新能源高效利用及储能技术;火灾动力学及建筑物理;数字能源技术开发与应用
教育背景与工作经历
代表性研究成果
荣誉与奖励
主讲课程

教育背景与工作经历

教育背景

2002.08  2005.07              香港理工大学  建设及环境学院      博士

1999.09  2002.06              西安交通大学   能源与动力工程学院    硕士

1995.09  1999.07              西安交通大学   能源与动力工程学院    学士


工作经历

2011.06 至今                    上海理工大学              讲师/副教授/教授

2015.09  2016.07              清华大学                      访问学者

2009.07  2011.05              栢诚(香港)              项目经理

2008.10  2009.06              艾奕康(香港)         高级工程师

2008.05  2008.06              柏诚(美国)              高级工程师

2006.02  2008.09              柏诚(上海)              高级工程师

2005.09  2006.01              香港理工大学              研究助理


社会团体职务

[1]   中国工程热物理学会传热传质分会第一届青年工作委员会委员;

[2]   中国锅炉与锅炉水处理协会燃烧技术委员会副主任委员;

[3]   中国锅炉与锅炉水处理协会锅炉技术委员会委员。


代表性研究成果

纵向项目

[1]   国家重点研发计划项目复杂条件典型燃烧设备能效评价N QI协同创新技术2021-2025

[2]   国家重点研发计划项目典型高耗能工业设备节能NQI技术集成及应用示范2018-2021

[3]   上海市自然科学基金面上项目纳米颗粒团簇效应影响复合相变材料传热的机理研究2020-2023

[4]   上海市2018年度国际科技合作项目太阳能光伏光热系统温控与能效强化机理研究2018-2020

[5]   国家自然科学基金方腔内移动物体及其产热引起的对流换热耦合机理研究2013-2016

[6]   上海市科委自然科学基金地铁隧道内污染物扩散中的流动传热传质研究”2013-2015


横向项目

[1]   数据中心高效浸没式液冷系统开发,2023-2024

[2]   油田能联网压缩空气储能系统开发,2023-2024

[3]   基于VR技术的3D燃烧信息集成系统开发2023-2024

[4]   智能相变分离混烃机组系统运行仿真软件开发2023-2024

[5]   防汛泵站排河口视频智能分析系统技术维护服务2023-2024

[6]   聚光太阳能光伏/热(CPV/T)耦合系统开发技术服务2023-2024

[7]   基于产学研战略合作的技术咨询服务,2021-2026

[8]   唐山冀东石油加热炉掺氨燃烧与污染物排放特性研究,2022-2023

[9]   埃塞俄比亚Abyssinia银行新总部大楼消防性能化设计,2022-2023

[10] 真空相变加热炉多相流动与传热模拟仿真研究,2022

[11] 香港中九龙线不同隧道隔热层设计CFD模拟,2022

[12] 香港某污水处理工艺设计参数优化CFD模拟,2021-2022

[13] 香港蓝田交通枢纽污染物控制CFD模拟,2021-2022

[14] 杭州国家电网机房空间冷流分配系统创新研究,2021-2022

[15] 榆神热电基于虚拟现实技术的电站锅炉信息系统开发,2021-2022

[16] 新疆某风电法兰工程防冻电伴热CFD模拟仿真分析,2021

[17] 新江湾城F1E地块项目中庭CFD模拟,2020

[18] 高原条件下锅炉安全和节能技术研究,2018-2019

[19] 高效油气分离装置技术研发,2018-2019

[20] 基于VR技术的锅炉3D信息集成网络系统开发与研制,2017-2019

[21] 义乌机场快速隧道运营通风和火灾模拟研究,2018-2019

[22] 利用相变材料控制太阳能光伏板温度的机理研究,2018-2019

[23] 燃烧器及其与锅炉配风优化设计技术服务,2018

[24] 上海富士达电梯轿厢风洞试验,2017

[25] 便携式燃烧器综合性能测试仪数据集成处理系统开发,2017-2018

[26] 极端条件下强制循环热水锅炉系统瞬间汽化数值模拟,2015-2017

[27] 高原地区热水锅炉系统瞬间汽化流动过程数值模拟及试验,2015-2017

[28] 质检公益性行业科研专项项目火筒加热炉炉内燃烧场研究与热负荷均匀装置研制2013-2014

[29] 地铁车站火灾情况下利用电梯疏散技术研究,2013-2014

[30] 中国辽宁某综合发展项目消防性能化设计咨询2012-2013

[31] 上海轨道交通16号线压力波模拟仿真与实验测试,2012-2014


SCI期刊论文

[1] Q.N. Zhao, X.M. Liu, A.Y. Jiao, H.T. Xu*, F. Liu and X.W. Liao. A simplified mechanism of hydrogen addition to methane combustion for the pollutant emission characteristics of a gas-fired boiler. International Journal of Hydrogen Energy, 2024(49): 1376-1390.

[2]  A.Y. Jiao, Z.N. Zhou, X.C. Yang, H.T. Xu, F. Liu, X.W. Liao, J.X. Liu* and X.M. Jiang. The crucial role of oxygen in NO heterogeneous reduction with NH3 at high temperature. Energy, 2023(284): 129272.

[3]  A.Y. Jiao, H.T. Xu*, F. Liu, X.W. Liao, J.X. Liu and X.M. Jiang. Mechanistic study on the effect of ammonia co-firing with pulverized coal on NO formation and reduction. Chemical Engineering Science, 2023(282): 119306.

[4]  Q.N. Zhao, F. Liu, A.Y. Jiao, Q.G. Yang, H.T. Xu* and X.W. Liao. Prediction model of NOx emissions in the heavy-duty gas turbine combustor based on MILD combustion. Energy, 2023(282): 128974.

[5]  Q.N. Zhao, J. Li, A.Y. Jiao, F. Liu, H.T. Xu* and X.W. Liao. Pollutant emission characteristics of the close-coupled selective catalytic reduction system for diesel engines under low exhaust temperature conditions. Fuel, 2023(354): 129303. 

[6]  C.Y. Zhang, Z.J. Ma, Z.G. Qu, H.T. Xu* and Q.G. Yang. Numerical energy and exergy evaluation for a multiple-layer latent heat storage unit enhanced with nanoparticles under different seasons. Journal of Cleaner Production, 2023(417): 138098. 

[7]  H.T. Pan, X.M. Liu, Q.G. Yang, H.T. Xu* and D. Xu. Three-dimensional Lattice Boltzmann study on structure optimization and heat dissipation performance of pin-fin heat sink integrated with phase change material. Journal of energy storage, 2023(71): 108233. 

[8]  S.Y. Zhang, Y.J. Mao, F. Liu, H.T. Xu*, Z.G. Qu and X.W. Liao. Multi-objective optimization and evaluation of PEMFC performance based on orthogonal experiment and entropy weight method. Energy Conversion Management, 2023(291): 117310. 

[9]  Z.Q. Luo, X.M. Liu, Q.G. Yang, Z.G. Qu, H.T. Xu* and D. Xu. Numerical study on performance of porous brick roof using phase change material with night ventilation. Energy and Buildings, 2023(286): 112972.

[10] C.Y. Zhang, N. Wang, H.T. Xu*, Y. Fang, Q.G. Yang and F. Karimi. Thermal management optimization of the photovoltaic cell by the phase change material combined with metal fins. Energy, 2023(263): 125669.

[11] Q.N. Zhao, Q.G. Yang, H.T. Xu*, A.Y. Jiao and D.H. Pan. Experimental study on pollutant emission characteristics of diesel urea-based selective catalytic reduction system based on corrugated substrate. Energy, 2023(267): 126475.

[12] S.Y. Zhang, Q.G. Yang, H.T. Xu* and Y.J. Mao. Numerical investigation of the performance of PEMFC with rib-like flow channels under different flow patterns. International Journal of Hydrogen Energy, 2022(47): 36254-36263.

[13] D. Xu, Z.G. Qu, Lu An, H.T Xu*, Q.G. Yang, Z.Q. Luo and H.T. Pan. Pore-scale study on the effects of randomly distributed void cavities on the thermal performance of composite phase change materials. Journal of Energy Storage. 2022, 55: 105715.

[14] C.Y. Zhang, N. Wang, Q.G. Yang, H.T. Xu*, Z.G. Qu and Y. Fang. Energy and exergy analysis of a switchable solar photovoltaic/thermal-phase change material system with thermal regulation strategies. Renewable energy, 2022(196): 1392-1405.

[15] S.Y. Zhang, S. Liu, H.T. Xu*, Y.J. Mao and K. Wang. Numerical investigation on the performance of proton exchange membrane fuel cell with zigzag flow channels. Frontiers in Chemical Engineering, 2022: 907873.

[16] SY. Zhang, H.T. Xu*, Z.G. Qu, S. Liu and F.K. Talkhoncheh. Bio-inspired flow channel designs for proton exchange membrane fuel cells: A review. Journal of Power Sources, 2022(522): 231003.

[17] S.Y. Zhang, S. Liu, H.T. Xu*, G.J. Liu and K. Wang. Performance of proton exchange membrane fuel cells with honeycomb-like flow channel design. Energy, 2021(239): 122102.

[18] S.Y. Zhang, Z.G. Qu, H.T. Xu*, F. Karimi, S. Liu and Q. Gao. A numerical Study on the performance of PEMFC with wedge-shaped fins in the cathode channel. International Journal of Hydrogen Energy, 2021(46): 27700-27708.

[19] H.T. Xu, N. Wang, C.Y. Zhang, Z.G. Qu* and F. Karimi. Energy conversion performance of a PV/T-PCM system under different thermal regulation strategies. Energy Conversion and Management, 2021(229):113660.

[20] Z.Q. Luo, H.T. Xu*, L.L. Feng, P. Lin and Q. Lou. GPU-accelerated lattice Boltzmann simulation of heat transfer characteristics of porous brick roof filled with phase change materials. International Communications in Heat and Mass Transfer. 2020, 119: 104911

[21] Z.R. Bai,Y.B. Miao, H.T. Xu*, Q. Gao. Experimental study on thermal storage and heat transfer performance of microencapsulated phase-change material slurry. Thermal Science and Engineering Progress  2020,17:100362

[22] Y. Fang, Z.G. Qu*, J.F. Zhang, H.T. Xu and G.L. Qi. Charging performance of latent thermal energy storage system with microencapsulated phase-change material for domestic hot water. Energy & Buildings, 2020(224) 110237.

[23] Y.H. Fang, H.T. Xu#, Y.B. Miao, Z.R. Bai, J.L. Niu* and S.M. Deng. Experimental study of storage capacity and discharging rate of latent heat thermal energy storage units. Applied Energy, 2020(275) 115325.

[24] Y. Fang, Z.G. Qu*, J.F. Zhang, H.T. Xu and G.L. Qi. Simultaneous charging and discharging performance for a latent thermal energy storage system with a microencapsulated phase change material. Applied Energy, 2020(275) 115353.

[25] H.T. Xu, N. Wang, C.Y. Zhang, Z.G. Qu* and M. Cao. Optimization on the melting performance of triplex-layer PCMs in a horizontal finned shell and tube thermal energy storage unit. Applied Thermal Engineering, 2020 (176) 115409.

[26] H.T. Xu, C.Y. Zhang, N. Wang, Z.G. Qu* and S.Y. Zhang. Experimental study on the performance of a solar photovoltaic/thermal system combined with phase change material. Solar Energy, 2020(198): 202-211.

[27] J. Chen*, C.X. Wang, G.J. Hu, H.T. Xu, P.W. Liu and X. Pan. Airfoil parameterization evaluation based on a modified PARASEC method for a H-Darrious rotor. Energy, 2019(187), 115910.

[28] H.T. Xu, Z.Q. Luo, N. Wang, Z.G. Qu*, J. Chen and L. An. Experimental study of the selective catalytic reduction after-treatment for the exhaust emission of a diesel engine. Applied Thermal Engineering, 2019(147): 198-204.

[29] H.T. Xu*, Z.Q. Luo, Q. Lou, S.Y. Zhang and J. Wang. Lattice Boltzmann simulations of the double-diffusive natural convection and oscillation characteristics in an enclosure with Soret and Dufour effects. International Journal of Thermal Sciences, 2019(136): 159-171.

[30] Q.L. Ren, H.T. Xu* and Z.Q. Luo. PCM charging process accelerated with combination of triangle fins and nanoparticles by lattice Boltzmann method. International Journal of Thermal Sciences, 2019(140):466-479.

[31] H.T. Xu, Y.B. Miao, N. Wang, Z.G. Qu* and X.C. Wang. Experimental investigations of heat transfer characteristics of MPCM during charging. Applied Thermal Engineering, 2018(144): 721-725.

[32] Z. Luo and H.T. Xu*. Numerical Simulation of Heat and Mass Transfer through Microporous Media with Lattice Boltzmann Method. Thermal Science and Engineering Progress, 2018(9) 45-51.

[33] T.S. Liang, H.T. Xu, Z.Z. ZhangJ. Chen* and M. Yang. Lattice Boltzmann simulations of double-diffusive convection in lid-driven composite cavity. Journal of Porous Media, 2020, 23(2): 121-137. 

[34] J. Chen, H.T. Xu*, Z.Y. Wang and S.P. Han. Thermal performance study of a water tank for a solar system with a Fresnel lens. Journal of Solar Energy Engineering, 2018, 140: 051005-1.

[35] H.T. Xu*, F. Karimi, J. Chen, M. Yang and S. Yu. Experimental investigation on a photovoltaic thermal solar system with a linear Fresnel lens. Journal of Energy Engineering, 2018, 144(3): 04018012.

[36] Q. Lou, C.Q. Zang, M. Yang and H.T. Xu*. Lattice Boltzmann simulation of immiscible displacement in the cavity with different channel configurations. International Journal of Modern Physics C, 2017, 28(11): 1750136.

[37] Q. Lou*, M. Yang and H.T. Xu. Wetting boundary condition in an improved lattice Boltzmann method for nonideal gases. Communications in Computational Physics, 2018, 23(4): 1116-1130.

[38] Q. Lou*, M. Yang and H.T. Xu. Numerical investigations of gas-liquid two-phase flows in microchannels. Proc IMechE Part C: J Mechanical Engineering Science, 2018, 232(3): 466-476.

[39] F. Karimi, H.T. Xu*, Z.Y. Wang, J. Chen and M. Yang. Experimental study of a concentrated PV/T system using linear Fresnel lens. Energy, 2017, 123:402-412. 

[40] M. M. Ur Rehman, Z.G. Qu*, R.P. Fu and H.T. Xu. Numerical study on free-surface jet impingement cooling with nanoencapsulated phase-change material slurry and nanofluid.  International Journal of Heat and Mass Transfer, 2017, 109:312-325.

[41] H.T. Xu, X.W. Liao, Z.G. Qu*, Y.Z. Li and J. Chen. Experimental study of the effect of a radiant tube on the temperature distribution in a horizontal heating furnace. Applied Thermal Engineering, 2017, 113:1-7.

[42] H.T. Xu, T.T. Wang, Z.G. Qu*, J. Chen and B.B. Li. Lattice Boltzmann simulation of the double diffusive natural convection and oscillation characteristics in an enclosure filled with porous medium. International Communications in Heat and Mass Transfer, 2017, 81:104-115.

[43] J. Chen, L. Chen*, H.T. Xu, H.X. Yang, C.W. Ye and D. Liu. Performace improvement of a vertical axis wind turbine by comprehensive assessment of an airfoil family. Energy, 2016, 114:318-331.

[44] H.T. Xu*, B.B. Li, J. Chen, Q. Lou, Z.R. Yan and M. Yang. Lattice BGK simulations of the double diffusive mixed convection in an enclosure with different outlet locations. International Journal of Heat and Mass Transfer, 2016, 92:158-172.

[45] F. Karimi, H.T. Xu, Z.Y. Wang, M. Yang* and Y.W. Zhang. Numerical simulation of transient forced convection in a square enclosure containing two circular cylinders. International Journal of Numerical Methods for Heat & Fluid Flow. 2016, 26(1): 307-327. 

[46] J. Chen, L. Chen, L. Nie, H.T. Xu, M. Yang and C.X. Wang*. Experimental study of two-stage Savonius rotors with different gap ratios and phase shift angles. Journal of Renewable and Sustainable Energy, 8(6), 063302(2016).

[47] C. Liu, J. Chen*, H.T. Xu, H.X. Yang, C.W. Ye and D. Liu. Wind tunnel investigation on the two-and three-blade Savonius rotor with central shaft at different gap ration. Journal of Renewable and Sustainable Energy, 2016, 8(1): 648-661.

[48] F. Karimi, H.T. Xu, Z.Y. Wang, M. Yang* and Y.W. Zhang. Numerical simulation of steady mixed convection around two heated circular cylinders in a square enclosure. Heat Transfer Engineering, 2016, 37(1): 64-75. 

[49] J. Chen*, H.X. Yang, M. Yang, H.T. Xu and Z.H. HuA comprehensive review of theoretical airfoil design approaches for the lift-type vertical axis wind turbine. Renewable & Sustainable Energy Reviews, 2015, 51:1709-1720.

[50] J. Chen*, H.X. Yang, M. Yang and H.T. Xu. The effect of the opening ratio and location on the performance of a novel vertical axis darrieus turbine. Energy2015, 89: 819-834. 

[51] B. Wei, M. Yang*, Z.Y. Wang, H.T. Xu and Y.W. Zhang. Flow and thermal performance of a water-cooled periodic transversal elliptical microchannel heat sink for chip cooling. Journal of Nanoscience and Nanotechnology, 2015, 15(4): 3061-3066.

[52] M. Yang*, Y.Y. Shen, H.T. Xu, M. Zhao, S.W. Shen and K. Huang. Numerical investigation of the nonlinear flow characteristics in an ultra-supercritical utility boiler furnace. Applied Thermal Engineering, 2015, 88:237-247. 

[53]H.T. Xu*, R.X. Xiao, F. Karimi, M. Yang and Y.W. Zhang. Numerical study of double diffusive mixed convection around a heated cylinder in an enclosure. International Journal of Thermal Sciences, 2014, 78:169-181.

[54] H.T. Xu*, Z.Y. Wang, F. Karimi, M. Yang and Y.W. Zhang. Numerical simulation of double diffusive mixed convection in an open enclosure with different cylinder locations. International Communications in Heat and Mass Transfer, 2014, 52:33-45.

[55] H.T. Xu*, F. Karimi and M. Yang. Numerical investigation of thermal characteristics in a solar chimney project. Journal of Solar Energy Engineering, 2014, 136:1-7.

[56] F. Karimi, H.T. Xu, Z.Y. Wang, M. Yang* and Y.W. Zhang. Numerical simulation of unsteady natural convection from heated horizontal circular cylinders in a square enclosure. Numerical Heat Transfer, Part A: Applications, 2014, 65:715-731.



荣誉与奖励

科技奖励与竞赛

[1]   2023第二届市场监管科研成果奖三等奖,国家市场监督管理总局,第二完成人

[2]   2023第九届中国国际互联网+”大学生创新创业大赛上海赛区铜奖,上海市教委,第一指导教师

[3]   2022中国机械工业科技进步奖三等奖,中国机械工业联合会,第一完成人

[4]   2022第八届互联网+”大赛上海高教主赛道银奖,上海市教委,第一指导教师

[5]   2021校企合作双百计划典型案例,中国高等教育学会,第一完成人

[6]   2021第二届全国机械工业设计创新大赛金奖,机械工业联合会,第一完成人

[7]   2019锅炉科学技术奖一等奖,锅炉与锅炉水处理协会,第四完成人

[8]   2019锅炉科学技术奖二等奖,锅炉与锅炉水处理协会,第二完成人

[9]   201720182020美国大学生数学建模大赛一等奖,指导教师

[10] 2015年第八届全国大学生节能减排竞赛一等奖,第二指导教师

[11] “十二五机械工业优秀科技成果,中国机械工业联合会,第二完成人


参与国家和行业标准制定

[1]  T/CBWA0024-2023《锅炉温室气体排放测试与计算方法》

[2]  T/CBWA0015-2022《铸铝冷凝燃气锅炉》

[3]  GB/T 36699-2018《锅炉用液体和气体燃料燃烧器技术条件》

[4]  GGCTS002-2018《空调产品PUE能效因子测试规范》

[5]  TGGCTS001-2018《微模块产品PUE测试规范》


授权发明专利

[1]  动态式叶片混合器,ZL 201610715763.3

[2]  储热式平板型太阳能集热器,ZL 201810399662.9

[3]  小型家用太阳能热电冷多联产系统,ZL 201811621444 .1

[4]  一种聚光平板型光伏光热一体化复合太阳能集热器,ZL2018103080025

[5] 基于纳米流体分频的家用太阳能热电氢储能利用系统,CN202210262261.5


主讲课程

本科生课程工程热力学、传热学、科技英语阅读与写作(双语)

研究生课程:高等热力学、高等传热学、传热学专论  


所属团队与核心课程

[1]  第二批国家线上线下混合式一流本科课程-工程热力学2022

[2]  清洁能源与装备技术-上海高水平地方创新团队(重点),2021

[3]  首批国家线上线下混合式一流本科课程-传热学,2020

[4]  上海高校外国留学生英语授课示范性课程,2018-2020

[5]  上海市教委重点课程《工程热应用与分析》,2017

[6]  国家级精品资源共享课-传热学,2014

[7]  国家级教学团队-热工教学团队,2009


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